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An Introduction to Enhancing Learning with Online Resources, Social Networking, and Digital Libraries Robert E. Belford,*,1 John W. Moore,2 and Harry E. Pence3 1Department
of Chemistry, University of Arkansas at Little Rock, Little Rock, Arkansas 72204 2Department of Chemistry, University of Wisconsin-Madison, Madison, Wisconsin 53706 3Department of Chemistry and Biochemistry, SUNY at Oneonta, Oneonta, New York 13820 *
[email protected] Our science and our society are in the midst of a digital revolution that is changing the way that we use information, communicate and share information with others, and participate in social groups to address problems. How will education in general and chemical education in particular respond to these dramatic changes? Early adopters are exploring a broad range of possibilities. This book is the first volume of a series of books which we envision to showcase the current state of the art based upon material presented in symposia at ACS national meetings, BCCEs, Online ConfChem conferences and other venue. It will be of interest to anyone who wants to enhance learning and involve students with the panoply of evolving information and communication tools that are available for scientific research and education. The World Wide Web has had a profound impact on scholarly communication and the dissemination of resources. Preparing students for this new environment will require significant changes in the educational process. At the same time, new kinds of computer software are making it much easier to create groups of people with similar interests. New tools, like RSS feeds, and social tagging are changing the way that © 2010 American Chemical Society Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
readers interact with information. Wikipedia, where articles are written and edited collaboratively by volunteers from around the world, has become a model for many similar efforts. This type of crowdsourcing opens up new avenues for information processing, research, and collaborative learning. Some argue that these successes are a prelude to a more general movement toward openness in the scholarly process. This book addresses these questions and their implications:
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How are cheminformatics and the digital revolution changing students’ ability to acquire information, and how can instructors take advantage of this to enhance learning? What learning opportunities arise as students deal with assessing the veracity of information acquired through disparate resources? What are suitable sustainability models for content development in the new open access, open source, open data, open publishing world? How do digital libraries support development of new resources, collections of resources, maintenance of resources, and communication among teachers and students? What new types of educational resources have been developed by open-source projects and what new opportunities do they offer educators? How can social networks, social tagging, wikis, and other tools best support and contribute to students’ learning? How are these new tools and attitudes affecting the traditional process of scholarly communication?
Several years ago, Carla Hesse, a prize-winning historian from UC Berkeley, wrote about her vision of the future of scholarship (Hess, C. Books in Time. In The Future of the Book; Nunberg, G., Ed.; University of California Press: Berkeley, CA, 1996; p 31.), “In the future, it seems, there will be no fixed canons of texts and no epistemological boundaries between disciplines, only paths of inquiry, modes of integration, and moments of encounter.” If her prediction is correct, and it seems to be coming true, this will have a major impact on all aspects of teaching and learning, including chemical education. It is important that educators, students, and the public become aware of the implications of online resources, social networking, and digital libraries for scientific education and research. Many opportunities are ripe to be seized and the contributors to this 2 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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book are at the forefront of determining which are most useful and effective.
Information and Communication Technologies (ICTs) are changing the way our society stores and communicates information. This ACS Symposium Series Book is a collection of papers that highlight various impacts these changes have had—and can have—on the chemical education community. In the chapters of this book we have brought together papers that cover a broad range of topics. These include generalized topics on information management, Open Science, Open Resources and the digital revolution, along with descriptions of specific resources such as the RSC ChemSpider, the Organic Reaction Explorer and various collections of the Chemical Education Digital Library. There are contributions on Open Source software development in the chemical sciences and the application of chemical education research to the development of animations and online learning environments. It is our intention that the collection of papers presented in this book will provide information that will be useful to traditional academicians, their students, and free agent learners who seek to take advantage of online resources in the pursuit of teaching and learning. Although this ACS Symposium Series Book is sponsored by the ACS Division of Chemical Education (DivCHED) (1), we recognize that ICTs impact scholarly communication in many disciplines. Thus we have included papers from non-chemistry sources as well as papers based on presentations at ACS National Meetings, Biennial Conferences on Chemical Education (2), online ConfChem (3) conferences, and the ChemEd DL (4). Although we have focused on chemical education, we hope that this book will be of use to anyone in who is interested in how ICTs can enhance learning, not only in formal and informal environments, but also with respect to scholarly activities in education and research. Two challenges in putting this book together were that we were using a traditional book to describe the rapidly changing concept of what a book is, and that a single book cannot adequately cover such a broad topic. Web 2.0 digital technologies such as wikis are creating dynamic, perpetually evolving, multi-authored texts that blur the distinction between readers and authors. Simply put, there is an inherent error in thinking that a static, hard-copy book can faithfully represent how Web 2.0 technologies have changed our conception of a book. With respect to the second challenge, we expect that this volume will be the first of a series of ACS Symposium Series Books on this subject, each representing a snapshot in time of this important field. We do not claim that any single book can be a comprehensive treatise on the subject, but we hope that this collection will be of value to both experts and novices who are trying to understand and take advantage of the evolving nature of education and scholarly communication in the chemical sciences.
3 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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Part I: Online Resources: Open Science and Open Resources Users of online resources are faced with two major questions: To what extent can I rely on what I am reading? and, How can I use it?—or Can I use it? The open nature of the World Wide Web has led to proliferation of both accurate and inaccurate information; in addition, a plethora of different approaches to copyright has been disseminated and repurposed by both novices and experts in appropriate and inappropriate ways. Thus a logical starting point is to look at the open nature of the Web and see what impact this has on education and on science in general. Even a concept like “Open Access” can have multiple interpretations, as John Willinsky points out in “Ten Flavors of Open Access to Journal Articles” in Appendix 1 of his book “The Access Principle: The Case for Open Access to Research and Scholarship.” (5) These flavors range from instant free access to material along with permission to create derivative works (the Budapest Open Access Initiative (6) definition), to delayed or partial open access with restricted usage (only subscribers get instant or complete access). All forms of open access involve access to material on the Web without paying a fee, but educators’ need to repurpose material leads to the concept of “Open Resources”, those that are open access in the Budapest Initiative sense, with copyright licenses like General Public License (GPL) (7) or Creative Commons (8) that allow for repurposing and production of derivative works. Two Open Resource sites of interest to educators are the United Nations Educational, Scientific and Cultural Organization Open Educational Resource (9) and SchoolForge.net (10). Chemical educators need to understand the impact of the open nature of online resources on both science and education. The concept of Open Science is a latent theme of several chapters in this book. A very important Open-Science community in chemistry is Blue Obelisk (11), a group of chemists, programmers and chemical informatics professionals who promote Open Science through the “three pillars of the Blue Obelisk movement”: Open Data, Open Standards and Open Source (ODOSOS) (11). All authors in this first section of the book have been involved with Blue Obelisk. Open-Science movements such as Blue Obelisk are far more important to chemical educators than simply the Open Resources they are creating. The movement is changing the way science is performed. Consider the four goals of Open Science as defined by Dan Gezelter in his OpenScience.org blog (12) essay: “What, exactly, is Open Science” (13) • • • •
Transparency in experimental methodology, observation, and collection of data. Public availability and reusability of scientific data. Public accessibility and transparency of scientific communication. Using Web-based tools to facilitate scientific collaboration.
This first section looks at several ways the Open Science movement is changing the way we do science and potential implications for chemical education. Part of the problem with reliability of the Web as a source of information stems from the fact that today’s search engines are not designed to assist the 4 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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user in critically evaluating the information delivered. There is a clear need for online services that can assist users in evaluating the accuracy of the chemical information they access and acquire. A new resource in this area is the Royal Society of Chemistry’s ChemSpider, a portal to online chemical information and resources. Antony Williams, one of the developers of ChemSpider, has provided a chapter, “ChemSpider: Integrating Structure-Based Resources Distributed across the Internet”, that describes it. ChemSpider not only aggregates data and links to both open and proprietary databases, but also includes a reviewed, crowd-sourced curation of data based on a hierarchical structure that helps users assess the data’s accuracy. The site allows for a variety of flexible search approaches including structure and substructure queries of a chemical data base containing almost 25 million unique chemical compounds. ChemSpider was not originally designed as an educational tool, but its developers understand the importance of chemical education and have provided interfaces that enable development of tools of value to educators. One such tool is the Spectral Game (14), in which students competitively associate spectra with structures. (Interestingly, the game can also be used in the curation process of published data.) Another tool, ChemSpider Synthetic Pages (CS/SP) (15), is a peer-reviewed online publishing platform for chemical synthesis reactions and procedures; it enables students to publish reactions without submitting a formal publication. Synthetic Pages also utilizes social networking functions by which authors can receive feedback on their work, thereby enhancing learning and helping students develop online reputations and collaborations. As educators, we need to realize that Wikis, Blogs, Podcasts, Social Networks and other Web 2.0 components not only afford us with new opportunities for enhancing learning, but also enhance our ability to communicate and perform research. One of the big questions for the future is: How will Web 3.0 technologies and the Semantic Web impact both education and scientific research? In “Using Semantically-Enabled Components for Social-Web Based Scientific Collaborations”, Omer Casher and Henry Rzepa provide an overview of the use of Web 2.0 and Web 3.0 technologies, including a discussion of how these components can advance research by enabling scientific communication both within and across disciplines. Web 2.0 technologies foster collaborations by enabling interactive sharing of information over the Web while Web 3.0 technologies enable sharing of information through software agents. The authors emphasize that such technologies are complementary, not competitive. Casher and Rzepa introduce the concept of the Semantic Web and current technologies that could enhance collaborative scientific research in a culture of Open Science. This chapter will give chemical educators a better understanding of the potential impact of the Semantic Web on how science is performed and of the technologies that are currently available. If ICTs are enabling Open Science, then it is imperative that chemical educators understand the evolution toward Open Science. Clearly ICTs have had a huge impact on software development. Through Web 2.0-enabled communities that have sprung up in association with Sourceforge (16), Github (17), Cpan (18) and similar collaborative environments, programmers are now able to share code and expertise in the spirit of collaboration based on a 5 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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common interest in a specific project without ever having to meet face-to-face. These communities have given educators with programming skills the opportunity to develop highly productive collaborations that have created educational applications that simply would not have yielded the financial return necessary for commercial investment. In effect, this has changed the driving force for software development from a corporate profit motive to the very practical needs of a widely dispersed community of educators. One open-source effort that is ubiquitous in chemistry is the Jmol molecular visualization project. “Web-Based Molecular Visualization for Chemistry in the 21st Century” by Bob Hanson, at present the principal developer of Jmol, gives us a feel for the current state of Jmol. It also provides insight into the evolution of open-source applications like Jmol and how development of such a resource can be driven by input from an involved user community. Through ODOSOS, Jmol has become much more than a molecular viewer: it is effectively a Semantic Web software application that, by interacting with other software applications, can both deliver chemical structures from key Web resources and create them itself. An example of Jmol’s versatility is its integration into the ChemEd DL WikiHyperGlossary (WHG) project. WHG is a glossary-generating program that automates the markup of digital text documents and Web pages. If a glossary term in the WHG is a chemical name, that name can be associated with an open-standard IUPAC InChI (19) chemical identifier. The identifier can be used to search the Models 360 (20) database of ChemEd DL; if the molecule is present in Models 360, clicking on its link will pop up a Jmol display to show electrostatic potentials, molecular vibrations (along with links to associated IR spectra), symmetry elements, or molecular orbitals. If the molecule is not part of the Models 360 database, a model is generated on the fly by passing the chemical identifier to other software agents. Thus a reader can submit to the WikiHyperGlossary a digital text document (MS Word, Adobe PDF…) or Web page containing the name of a compound and have nearly instant access to that compound’s three-dimensional structure, spectra, and other associated information. This has been made possible by ODOSOS. The last chapter of this section looks at Wikipedia, which has become an important online source of chemical information. A significant fraction of faculty and students question the reliability of Wikipedia. For example, in 2009 and 2010, general chemistry students at the University of Arkansas at Little Rock were asked: “Do you use Wikipedia?” and “Do you consider Wikipedia to be a valid source of information?” The most common response to the first question was yes; however many of the students who responded positively to the first question responded no to the second. Responses such as, “No, because my teachers tell me I cannot trust Wikipedia” were common. This contradiction indicates inadequate understanding of Wikipedia’s chemistry content by many educators. Martin Walker’s chapter, “Wikipedia as a Resource for Chemistry”, should help students and educators better understand this valuable resource. Better understanding should lead to more effective use of Wikipedia. Walker points out that understanding what Wikipedia is not is fundamental to understanding what it is. Wikipedia is neither a textbook nor a place to publish opinion or original thought; every contribution should have references 6 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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and citations to the original source. Emphasis on verifiable information is critical to doing good science, so Wikipedia provides a microcosm akin to scientific communication. That is, understanding how to ascertain the appropriateness and verifiability of information is an important skill no matter what the information source, and we do not want our students to uncritically believe anything they read. We want them to question what is written and to learn how to dig deeper and evaluate the source of information before using it. Walker describes several specific chemistry-related Wikipedia features, such as the “Chembox”, and discusses ongoing efforts and issues associated with curating Wikipedia’s chemistry content. He also points out that Wikipedia and WikiCommons (21) are a good source of images, graphs and charts. This leads to a discussion of the importance of teaching students how to use online material properly with respect to copyright when they incorporate it into their own classroom projects such as papers and PowerPoint presentations. The chapters in this first section are intended to provide better understanding of specific online resources and enhanced appreciation of the importance of Open Science and Open Resources in chemical education and in the pursuit of science
Part II: Social Networking and Chemical Education Over a decade ago, Clayton Christensen described the difference between sustaining and disruptive technologies (22). Sustaining technologies improve current practices in a company or organization without requiring major alterations in the way that things have always been done; disruptive technologies require dramatically different ways of operating. Christensen noted that well-established, successful companies often resist major changes in their business models and may be forced into bankruptcy by new competitors who are willing to embrace disruptive technologies. To date, professors and administrators appear to have been more willing to accept sustaining technologies, like PowerPoint and clickers, than to adopt practices that disrupt traditional methods of teaching. Information is so fundamental to the chemical enterprise that significant changes in the way it is organized, used, and stored are very likely to be disruptive. This section of the book describes ongoing revolutions in information technology and suggests ways in which higher education might respond. The term “digital divide” has historically referred to a division between those who have or do not have computers. A more dangerous separation may well be that some people will not have the training and experience needed to use computers in more sophisticated and more powerful ways. This divide will depend upon appropriate training in the use of new technologies as well as access to online information sources. Many colleges subscribe to at least a basic online set of American Chemical Society journals, but students at some smaller colleges may not have online access to the scientific literature they need to become proficient at modern information management. Even institutions that do have access may not all teach the skills that enable their students to become effective chemists. The papers in this section attempt to provide a better understanding of potentially disruptive information 7 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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technologies and to answer the question, "What kinds of skills should current undergraduates learn?" In “Sceptical Chymists Online”, Burke Scott Williams provides a historical perspective on changes that are occurring in science and science education. He suggests that much of science continues to be based on the assumptions of the Gutenberg era even though the Internet has begun to change the existing structure. Williams contends that, based on the time that it took for the printing press to change society, this may be a slow revolution—one that will take place over the coming century. Since the 17th Century, science and science education have shifted from the Village mode, small groups with strong personal ties to each other, towards a structure that is best described as a mixture of the Cathedral and the Bazaar. Decision making in the Cathedral mode is strongly hierarchical, whereas it is diffuse and informal in the Bazaar mode. Williams suggests that the Internet is pushing society more strongly towards the Bazaar mode. Williams observes that the Scientific Revolution was brought about by improved communication (the printing press), combined with Bacon’s experimental method. While there have been many changes in communications since the 17th Century, the social aspects of science have remained relatively small (the research group, the small, intimate conference). In Christiansen’s terms, changes have been sustaining for a long time. The Internet now can support huge social networks of scientists—networks that are more conducive to the Bazaar than the Cathedral. Despite this, science teaching continues to follow a Cathedral-like, highly institutionalized organizational pattern. As science invariably moves towards a more open organization structure, it is essential that the educational process keep pace, even though the changes required may well be disruptive. In “Creating and Using a Personalized Information Management System”, Pence and Pence argue that the proliferation of online information sources has made information overload an increasingly critical problem—one that must be addressed in undergraduate chemical education. They suggest that powerful new tools be introduced at the undergraduate level so that future chemists can work more effectively in the modern networked environment; examples are microblogging, social tagging, and Really Simple Syndication (RSS). Microblogging sites, such as Twitter, allow an individual to create a network of people with similar interests who collectively search for and share new information. Really Simple Syndication automates the search process, delivering the latest news from a variety of sources to a single, personal Web page. Social tagging, such as Delicious, Diigo, or Connotea, helps an individual organize information after it has been located and identified. Google Jockey is somewhat different, since it is designed to introduce a visual component into seminars and other classroom activities where normal methods for introducing images are not effective. Pence and Pence describe specific examples of successfully integrating such technologies into their classrooms. Each technique might well be classed as sustaining, but the overall impact of all these changes seems more likely to be disruptive. The authors argue that, although a few students may have encountered these Web technologies outside the chemistry classroom, most lack 8 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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the comprehensive understanding that results from systematic training applied to situations that chemists encounter in their professional careers. Losoff and Pence, in “Preparing for the New Information Paradigm”, argue that chemical education should reflect changes in the way chemical research is being done. Online journals are altering access to information: more rapid distribution of articles; easier access to supporting material; faster and more comprehensive searches; and inclusion of full-color graphics, video clips, and animations. Even more disruptive developments are probably ahead. Digital technologies, especially online scholarly journals and eBooks, are linking articles, databases, and people in new ways that produce new patterns of literature use. The World Wide Web connects more than Web pages: it connects people who are building extended scholarly research networks. A loosely organized movement is calling for "open chemistry". This process is still in the early stages but will probably accelerate in the future to create more sophisticated methods for connecting. Portable devices like iPads and smartphones will contribute to a mix that will make all information available from any location, creating a virtual information commons.
Part III: Online Resources: Pedagogy and Curriculum Chapters in the first two sections of this book demonstrate many facets of the new milieu created by information and communication technologies. The last two sections shift the focus to a more practical vein: how ICTs can actually enhance learning. How is the role of the textbook evolving? What guiding principles do learning theories provide for developing online activities and animations? How are early adopters integrating these technologies into their curricula? While it is impossible to represent every facet of this expanding field, we hope that these chapters will be useful to those who want to use ICTs in their classrooms. The digital revolution’s impact on the publishing industry, both within and outside academia, is a theme common to many chapters in this volume. The textbook is the repository of information in traditional academic curricula, so one could ask, do students really value textbooks? The flourishing used-textbook industry is one indication that they do not—except in the specific course for which the book was designed. Unpublished data from Shorb and Moore, authors of a chapter in Part IV, indicates that only about two thirds of students use their textbook extensively even in the course for which it was designed. Although students spend a lot of money for textbooks, they apparently do not consider textbooks to have long-term value. When the textbook goes online, it becomes much more adaptable to a student’s needs and interests. One can envision a future “chemistry eBook” where a student has a single “book” containing the textbooks of all classes from first year to graduation and also containing the student’s personal notes, annotations, problem-solving efforts, links to other sources, and more. David Lubliner has outlined the evolution of eBooks in his chapter, “Integrated Learning Environments: From eBooks to e2Books; From e-Learning 3.0 to e-Knowledge and Beyond”. Lubliner defines an eBook as a static 9 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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“electronic counterpart of a printed book” that can be viewed through electronic devices, and an e2Book as a dynamic eBook that uses semantic terminology to link concepts with both internal and external data sources and knowledge repositories. This can result in an Integrated Learning Environment (ILE) which Lubliner defines as an “evolutionary environment that links dynamic books, knowledge repositories and provides organic growth to ensure the relevancy of the learning environment”. He presents results from the implementation of an ILE, the Constructivist Unifying Baccalaureate Epistemology (CUBE), in the computer sciences program at the New Jersey Institute of Technology (NJIT). Students who utilized the CUBE for two years received 25% higher mean scores on a content examination than students who did not utilize the CUBE ILE. Although the work at NJIT was in computer sciences, chemical educators will find much of interest in their experiences. Are textbooks evolving towards configurable e2Books where students’ eBook readers not only keep all of the information of an entire degree program at their finger tips, but also connect the topics of upper level courses back to their foundation courses? Such “degree level books” would span different disciplines. If a student in physical chemistry needed help with calculus an e2Book could direct the student to the "text" the student used in calculus. Likewise, a person studying an upper level biology course could be seamlessly connected with the foundation chemistry material. It would all be in the student’s degree level e2Textbook. Digital technologies also enable external visualizations in the form of animations and simulations that novices can use to develop understanding. It is important that educators be aware of what research has shown about developing learning activities based on these technologies. Roberto Gregorius’s chapter, "Good Animation: Pedagogy and Learning Theory in the Design and Use of Multimedia", provides an overview of this important aspect of using ICTs to enhance learning. An activity’s design should depend on its goals. Gregorius suggests that goals can determine when to apply behavioristic, cognitivistic, and social constructed or situated learning perspectives. If an animation was designed to promote learning in nomenclature and balancing equations, then digital games and drills that enhance rapid response skills in a behaviorist fashion would be appropriate. If the goal shifts from rapid response to the method by which an answer is obtained, then the design needs to be interactive and based on cognitivist research. What the learner brings to the lesson guides situated learning activities, which should be tunable to the learner’s "zone of proximal development". The activity should be at the fringe of what the learner can do without guidance. Gregorius also presents design parameters for developing multimedia; these are based on Mayer’s work on cognitive load and dual-coding theory. Finally he introduces the Inductive Concept Construction (IC2) Learning System, an eBook that utilizes these concepts. It is clear that no matter what methods or tools are used for instruction, a major challenge is to identify a student’s zone of proximal development and then provide lessons tuned to it. By mating digital technologies with knowledge space theory, it is possible to create a knowledge map and identify an individual’s knowledge state within a knowledge domain. This effectively identifies the zone of proximal development and allows lessons to be generated on a student’s knowledge fringe. 10 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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In their chapter, "Reaction Explorer: Towards a Knowledge Map of Organic Chemistry To Support Dynamic Assessment and Personalized Instruction", Chen et. al. describe development of "Reaction Explorer: Organic Chemistry Tutorials" (23), which is now distributed commercially via WileyPLUS. This rules-based program uses 1,500 reaction rules as knowledge items from which a knowledge map is created in the domain of organic synthesis and mechanisms. The authors then describe how they create a knowledge state model by assessing a student’s success/failure rate solving problems. The model is based on knowledge items associated with a problem, and on associations and dependencies of those items. It allows them to predict the probability that a student can solve a new problem. A directed problem selector can then generate problems on a student’s knowledge fringe, which is effectively the zone of proximal development. What are the challenges and rewards of offering a course online? How does one go about designing such a course? Can an online course be successful? Tomasik and Moore answer these and other questions in “Site Under Construction: Designing a Successful Online Course”. As part of the education/outreach program for the NSF-sponsored Nanoscale Science and Engineering Center (NSEC) at the University of Wisconsin−Madison, the authors designed and offered an online course, Nanoscience for Teachers. The purpose of the course, which was initiated in 2006 and continues to be offered, was to provide high school teachers with appropriate background in nanoscience and nanotechnology and to encourage them to include nanoscience topics in their courses. In both of these regards the course has been successful: teachers have created units on nanoscience, used them with students, and shared them with other teachers. One challenge faced by those offering online courses is that unless the course is well designed the student dropout rate may be greater than in a similar face-to-face course. This depends in part on the course content, how the content is presented online, the means of communication among participants and with the teacher, and the degree of interactivity the course structure affords. During early offerings of the online nanoscience course, these aspects were explored through formative assessments and the course design was changed accordingly. Steps were taken to assure high quality interactivity of participants with the course content, with the instructor, and with peer students. Interactivity included: weekly chat sessions with practicing nanoscientists; online forums for discussion among students, teachers, and experts in nanoscience and peer review by course participants of the lessons being developed by other course participants. Another challenge is obtaining content that can be used without violating copyright. The authors emphasize that course designers must consider copyright with respect to all content and work with librarians and others knowledgeable in this area. Fair use is not a simple subject and different universities and school systems may have different interpretations of what is and is not appropriate. In the case of Nanoscience for Teachers, it was often possible to use materials that were copyrighted but that had been licensed for use by all students by the university offering the course. This license extended to students whether or not they were physically on campus because access to the course was restricted by the course management system (Moodle) within which the course was developed. 11 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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Finally it is crucial that an online course undergo continual formative evaluation. Both the tools available to course designers and the expectations of student participants are continually changing. So are the copyright permissions for content and fair use. What works one year may not work the next. The equivalent of dog-eared lecture notes is not an option—which may be another advantage of an online course! This section deals with a general view of the options available to those designing online course materials and how learning theory and chemical education research can be applied to an online course and its components. We hope it provides insights that will improve online courses and that it encourages readers to develop their own online courses or course components.
Part IV: Digital Libraries: Creating, Refining, Storing, and Disseminating Online Resources What is a digital library? Why should I use a digital library? The name “digital library” connotes similarity to a traditional library: That is true in the sense that a digital library is a collection of online items that can be used for research and to support learning, but digital libraries have many more dimensions. For example, when NSF’s National STEM Digital Library (NSDL) project (http://nsdl.org/) was initiated in 2000, it began by collecting and cataloging online content for both education and research. So that each item could be retrieved easily NSDL assigned metadata keywords and operated a search engine that located resources by keyword. During its decade of existence, however, the NSDL has continually expanded its scope and facilities and identified new directions in which it needed to move to serve its constituencies. The NSDL’s collections in chemistry, held by the Chemical Education Digital Library (ChemEd DL, http://www.chemeddl.org/), are typical. They include a broad range of content: many hours of streaming digital video showing chemical reactions, apparatus, and laboratory techniques; quiz and examination questions including multimedia that can be delivered via Web-based course management systems; and Jmol molecular and crystal structures that can be manipulated with a mouse and that can display molecular orbitals, vibrations, symmetry, and other properties. The NSDL and its constituent groups such as ChemEd DL also serve as curators of the collections, keeping the content current. This involves dealing with issues such as URL rot, updating video and other content to meet new standards, and modifying content for dissemination via new modalities such as smartphones or iPads. NSDL’s creation in 2004 of Pathways projects—a means of tailoring the NSDL to serve the needs of a specific discipline or some other well defined audience—is an example of its continual evolution. In 2010, ChemEd DL is one among nearly 20 NSDL Pathways. The Pathways represent most scientific disciplines, groups such as public broadcasting and science museums, and audiences at specific educational levels, such as middle school or two-year and community colleges. A new Pathways project was initiated in 2010 that will concentrate on aiding teachers and school districts to incorporate NSDL resources 12 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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into courses and curricula. Through its many specialized Pathways, NSDL serves as a focus for communities that are creating and using online teaching and learning materials, as an aggregator of individual learning objects into larger modules that can be used by teachers and students to teach sizable portions of content, and as a national group that can work with state education agencies and individual school systems as well as teachers to bring highly effective online resources to students from K-16 and beyond. This broader scope has resulted in a change of name (but not abbreviation) to National STEM Distributed Learning. The importance of digital libraries in furthering educational goals is nicely exemplified by several chapters in this book. “Instruction Online: Core Components for Re-Use” by Yaron et al. describes the ChemCollective digital library and illustrates how online instructional materials from this project have been created and continually improved by a community that involves programmers, instructional specialists, content experts, and users (teachers and students). The authors contend that digital libraries can contribute to fundamental changes from existing instructional techniques, resulting in significant improvements in learning. They can do this by building and encouraging communities to develop and try new approaches, and by providing the means online by which members of such communities can evaluate and incrementally improve the new approaches. This requires use of technologies that enable relatively quick and easy modification of instructional materials by people who are not expert in information technology. Some examples of materials in the ChemCollective digital library are the Virtual Laboratory collection, a stoichiometry course, an equilibrium course, and Core Ideas in Molecular Science (CIMS). The Virtual Laboratory provides a means for students to do simulated laboratory work online much faster than it could be accomplished in a wet laboratory. In addition, the entire community of users can modify and improve experiments through the digital library interface. The online stoichiometry course provides a means by which students anywhere in the world can review what is perhaps the most important fundamental chemistry skill—one that many other disciplines count on general chemistry courses to teach well. The ChemCollective equilibrium course illustrates a different approach to teaching this important topic—an approach that has more than doubled student performance. CIMS is a collection of interdisciplinary instructional modules that have been tailored to specific disciplines as a means of encouraging teachers in each discipline to use them. One module, for example, uses molecular-scale animations to teach the ideas of energy, entropy, and Gibbs energy as applied to chemical equilibrium. All of the items in the ChemCollective have benefitted from honing by users and by those from other disciplines in different NSDL Pathways. “Developing ChemPRIME: Transforming the Didactics and Pedagogy of the General Chemistry Course with a Wiki Text” by Ed Vitz is another illustration of the usefulness of digital libraries. ChemPRIME (Chemical PRinciples through Integrated Multiple Exemplars) combines an idea that is more than a decade old (but nearly impossible to achieve at the time it was conceived) with the power of a wiki on a server operated by the ChemEd DL. The idea is that many students would be attracted to chemistry if they could see more clearly how chemistry is 13 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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applied in the fields of their primary interest, but that it is also beneficial to retain a logical structure for chemistry as a discipline so that students can appreciate the relationships among chemical facts and theories. A wiki is ideally suited to storing and serving alternative approaches that illustrate applications of chemistry topics in a variety of fields; a wiki also enables a broad range of teachers (and even students) to contribute such alternative approaches. ChemPRIME applies this approach to the general chemistry course. Many academic degree programs, such as engineering, biology, pre-medicine, computer science, physics, or geology, require general chemistry—and for good reasons. However, it is not clear to students that the considerable time and effort they spend on studying general chemistry reflects the actual benefit they will gain. Benefits would be more obvious if each discipline had its own chemistry course that was fine tuned to the needs of that discipline. This would allow students to learn via exemplars from the discipline of their choice and within the context of their interests. Realistically, however, even a large school cannot afford to offer the number of general chemistry courses that would be required to accommodate all student interests. Typically general chemistry instructors use a textbook for chemistry majors, which cannot promote students’ sense of the importance of chemistry to their disciplines nearly as well as a textbook fine-tuned to their major. ChemPRIME has scanned, digitized, and converted to wiki format a typical general chemistry textbook, “Chemistry” by Moore, Davies, and Collins. This wiki textbook provides a complete treatment of the content usually encountered in a general chemistry course; in the wiki this is called “CoreChem”. Ten “tracks” are being created parallel with the CoreChem, representing interests ranging from chemistry in everyday life to chemistry in physics and astronomy. Each track consists of many exemplars; when complete, the wiki will contain one or more exemplars in each track for each CoreChem topic. The wiki enables a variety of authors to enter exemplars into each track. Usually they begin with the CoreChem topic and then apply the concept to the track’s subject area, fine-tuning the presentation and examples to the other discipline. Thus each of the ten tracks teaches the same concepts as CoreChem, but each embeds the concept in the context of another discipline or area of student interest. Consequently students in environmental science, geology, or biology would all learn about heat capacity, and all would learn through exemplars that were relevant to their interests. A wiki allows this to be done in a dynamic way by having participants in the general chemistry community contribute exemplars in their areas of interest. Contributors to the wiki become members of a general-chemistry community in the digital library. The wiki format of ChemPRIME affords a teacher great latitude in specifying which topics should be studied in what order. Students also have great latitude in deciding which tracks or exemplars to study. But the wiki is not ideally suited to presenting an online textbook in the most approachable format. A wiki is dynamic—changing whenever someone edits an entry—and navigation in a wiki is limited. “The ChemPaths Student Portal: Making an Online Textbook More than a Book Online” by Shorb and Moore describes a digital-library service of the ChemEd DL that addresses the problems of wiki-based content. ChemPaths enables a teacher to specify a path through the wiki content and restrict the content 14 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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to a snapshot of the wiki taken at a particular time. Thus the order of presentation of the content can be structured as a teacher desires (for example, atoms first or chemical reactions first), and the content remains unchanged during a course. ChemPaths can be likened to a path of stepping stones with other shorter paths off to the side. It enables a student to follow the order of topics in CoreChem, for example, but to deviate to exemplars in one or more other tracks and then easily return to the main CoreChem path. Or a path could be specified that involves a track as the main focus, and a student could explore CoreChem as one possible side-trail. ChemPaths enables a variety of pedagogical approaches that are not available in a printed textbook. Thus teachers need not all adopt the same approach to designing what students will see when studying a given topic. The interface design of ChemPaths was based on research in hypertext learning and visual learning. It combines interactive molecule viewers (Jmol), embedded videos, and animations with explanatory text, affording students multiple representations of the same concept. Students can obtain definitions of terms by mousing over words, and links are provided to topics closely related to the one being studied. A periodic table, data tables, and the table of contents of CoreChem are always a mouse-click away. Online quizzes provide feedback including links to the relevant sections of the online textbook. This chapter describes the theories from which the design was derived and how an integrated learning system was developed for online delivery. This learning system has been tested in courses enrolling hundreds of students. Student feedback was obtained both during a course and at the end, and such feedback has led to changes in the delivery system as well as how students are introduced to it. Questions that had to be addressed include: accessibility for students with disabilities; means by which students can annotate, highlight, and bookmark text; organization and presentation of content and navigation; and students’ skills in using online materials compared to printed materials. The authors found that it is useful at the beginning of a course to introduce students to techniques for using an online textbook and even to provide a quiz or tutorial that prompts students to explore and use various features of the online medium. It is apparently a fallacy that all students are familiar with and comfortable with an online delivery system. There is almost certainly a lot more for us to learn by observing real students in a real course as they interact with this new learning aid. In “Building an Online Teaching Community”, Reisner et al. describe another aspect of digital libraries: building a community and providing for communication among its members using Web 2.0 tools. They describe the growth of the Interactive Online Network of Inorganic Chemists (IONiC), a community of practice, and IONiC’s development of a Web interface and online repository, VIPEr (Virtual Inorganic Pedagogical Electronic Resource). The authors, who are mostly from primarily undergraduate institutions, state at the beginning, “We never set out to build an online community.” But they did set out to communicate, spurred by the fact that in the smaller colleges where most of them teach there is usually only a single inorganic chemist—who yearns for professional discourse with others who have similar interests. The formation of IONiC came at a fortuitous time, because Web 2.0 technology was becoming available that 15 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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enabled much richer communication: videoconferencing, cloud-based workflows, long-range collaborations, and close personal relationships. One aspect of VIPEr that perhaps runs against the grain for many who are used to the traditional submit, review, evaluate, publish or decline process of peerreviewed journals is the relative ease of posting materials. A post must be approved by a member of the leadership group, but then it is released to the public and the review process occurs post publication. Often a review consists of comments from users of the material and is based on actual classroom use. This is a sensible way to get thorough evaluations but does not carry the cachet of a peer-reviewed journal. This is an aspect of publication that is worthy of considerable thought and debate. Is prior peer review necessary and desirable in a world where it is easy and convenient for any user to post a review after publication? Will enough users of materials be willing to take the time to contribute reviews and comments, no matter how easy it is? Will tenure committees accept and approve of a process of publication followed by review? Building the IONiC/VIPEr community benefitted from several factors: an enthusiastic, actively communicating leadership; a latent need for communication; demonstrable benefits that maintained momentum; occasional face-to-face meetings; a medium for sharing information that is easy to use; commonality of interests combined with breadth of membership; a community that is big enough, but not too big; and a collective sense of humor, a mascot, and lots of fun. The online community that IONiC has created exemplifies all of these characteristics. This chapter is a must-read for anyone who aims to create a community of any kind, because it contains a great deal of wise counsel. More important, it is just fun to read! Like the Web itself, the digital library is a constantly evolving work in progress. Like all digital libraries, the NSDL, the ChemCollective, IONiC/VIPEr, and the ChemEd DL have evolved significantly since their inception. They will evolve even further in the future, as new tools become available to facilitate storage, retrieval, and use of high quality online instructional materials, to enhance communication and community building, and to provide new means by which student learning can be encouraged and expanded. Stick around. The fun has just begun!
Part V: Looking Ahead Despite the wide variety of the techniques discussed in this book, the editors clearly understand that not every important development in instructional technology has been covered. This is not due to any lack of ability or foresight on the part of our contributors, but rather due to the massive and rapid nature of the changes that are currently happening. The educational process is being reshaped not just by the developments reviewed in this book, but also by new software and new devices. There are several such topics which we hope to cover in future ACS symposia, online conferences such as ConfChem (24), and subsequent volumes of this series. 16 Belford et al.; Enhancing Learning with Online Resources, Social Networking, and Digital Libraries ACS Symposium Series; American Chemical Society: Washington, DC, 2010.
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Pioneering work in several areas is ongoing. Cloud computing, where software does not reside on the local computer but is accessed through the World Wide Web, promises new opportunities for collaboration and organization (25). A few audacious teachers have demonstrated that virtual worlds, like Second Life, can be an effective venue for chemical education (26). The social networking applications that have grown so rapidly over the past decade can also have real value for learning. eTextbooks will probably become increasingly important in the future, but there is also a strong possibility that content will become disaggregated and learning modules may become a supplement or replacement for textbooks (27). Online learning seems to be generally accepted by educators, and there is increasing interest in hybrid approaches that combine online activities with the traditional classroom. Distributed and transmedia narratives are creating new types of literacies that our students need to understand. Digital electronic devices are proliferating faster than a book can keep up. They continue to become faster, smaller, and cheaper, creating a succession of new educational capabilities. An obvious example is the ubiquitous cell phone, which has become a powerful handheld computer with Web connectivity. Many people take these devices with them everywhere, creating a 24/7, always-on world of virtual information accessibility. It remains to be seen how these might best be used for education. These "smartphones" are combining with augmented reality to create a whole new range of applications for the chemistry classroom (28). The popularity of the Apple i-Pad is already inspiring a plethora of clones, which may well make gesture-controlled navigation the standard computer interface of the future. The Microsoft Kinect is designed to be a game system, but developers are already creating scientific applications (29). If the Kinect redefines the way humans interact with computers, there is little doubt that it will also have a significant effect on education (30). Some suggest that the rapid rate of change argues for teachers to wait until stability is reestablished before investing their effort on new technologies. This is not a viable strategy. The pace of change is accelerating, and there is a real need for broad-based experimentation to explore the pedagogies that must be developed to make full use of the new educational environment. Although it is impossible for a single individual to try all of the technologies, it is hoped that the chapters in this book will encourage many teachers to try individual techniques that appear most useful to their needs. Now is the time to explore new ways to support and foster student learning.
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